Sol-gel based matrix

ABSTRACT

A method for the production of a sol-gel based matrix resulting in a sol-gel based matrix with high stability and high porosity. The sol-gel based material may be used for the production of a composite or sensor suitable for monitoring analytes.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.15/028,600; filed Apr. 11, 2016, and now U.S. Pat. No. 10,233,328 issuedMar. 19, 2019, which is a National Stage of International ApplicationNo. PCT/DK2014/050341, filed Oct. 24, 2014. The entire disclosures ofeach of the above applications are incorporated herein by reference.

FIELD

The present invention relates to methods for the production of sol-gelbased matrixes as well as sol-gel based matrixes obtainable by suchmethods. The sol-gels of the present invention are useful for variouspurposes including use in sensors for measuring of pH, radiation, oxygenconcentration etc. due to their high stability and porosity. Compositescomprising the sol-gels of the present invention and a platform ofmicrostructure area are also disclosed. Methods for preparing thesecomposites or sensors are provided as well.

BACKGROUND

First generation optical sensors are currently being introduced inbiotechnological production platforms. The sensors are composed of fivedifferent units, excluding the fiber optical connectors: i) lightsource, ii) substrate, iii) matrix, iv) indicator dye components, and v)detector.¹⁻⁵

Light sources and detectors are highly developed and is just a questionof costs. The substrate has to be chosen based on the platform in whichthe sensing will take place, typically a glass or a polymer support isused. The key parameter regarding the substrate is that the matrixmaterial must be able to be at least partly immobilized in or on thesubstrate.

The wish list for the matrix material is long: the matrix materialshould allow the analytes to pass through the film as unhindered aspossible, it should encapsulate the sensor molecules, it should betransparent and have a low auto-fluorescence, and it has to be stable inbiological media for extended periods of time. The indicator dyecomponents may be either a single ratiometric pH responsive dye, or twodyes with similar properties. The latter is only possible if thephysical stability of the matrix ensures that no dye is lost to themedium.

The benchmark in materials for optical sensors has been set in sensors,where fluorescein has been used as the indicator dye component;⁴⁻⁸despite the poor photostability of fluorescein The critical parametersare the response time of the sensor, the leakage of the dye, thestability of the signal and the response to pH. While leakage of thehighly water soluble fluorescein from the prior art optical sensors hasnot been completely removed,⁹ other more lipophilic dyes have beensuccessfully encapsulated in sol-gel matrices.^(10, 11) However, evenlipophilic dyes may be prone to leakage during long term use or inlipophilic/amphiphilic environments.

Preparation of organically modified silicates (ORMOSILs) using alkyl and3-glycidoxypropyl substituted trialkoxysilanes and variouspolymerization conditions have been reported previously in thescientific literature.^(1, 12, 13) Leakage has been controlled eitherusing apolar additives^(11, 14) or by attaching the dyes to bulkymacromolecules.^(6, 7, 15, 16) It has been reported that Lewis acids canbe a catalyst for polymerization of 3-glycidoxypropyltrialkoxysilanes,accelerating both the polyether and the polysiloxaneformation.^(12, 13, 17)

WO 2009/020259 discloses in example 2 a method in which3-glycidoxypropyltrimethoxysilane (GPTMS), methyltriethoxysilane (MTES),ethanol (6.95 mM) and 35% HCl were mixed together and stirred at roomtemperature for three days to induce a condensation reaction. To thesol-gel solution thus prepared, 1 mM HPTS solution, which had beendissolved in ethanol was added to give a HPTS mixture solution. The HPTSmixture solution was evenly coated onto the bottom surface of wells of amicrotiter plate to prepare a fluorescent sensing membrane that can beused for detection of carbon dioxide. The sol-gel solution comprisingcoated HPTS was dried at room temperature for five days and furtherdried at 70° C. for two days for improving a mechanical strength andsurface smoothness. WO 2009/020259 uses HCl as the initiator and theindicator moiety (HPTS) is non-covalently attached to a silane.

WO 2004/077035 discloses a CO₂ sensor comprising a pH-indicator and aporous sol-gel matrix. The pH-indicator may be hydroxypyrenetrisulfonate (HPTS) and immobilised in the sol-gel. The sol-gel may beprepared from the monomer ethyltriethoxysilane (ETEOS). In the specificmethod, two silanes are used (trimethylsilylpropane andtriethoxysilane). However, none of the silanes suggested in thedescription contains an epoxy group. Furthermore, the indicator moietyis not covalently linked to a silane.

WO 12/032342 discloses a sensor comprising a sol-gel layer incorporatinga phosphorescent material, such as ruthenium oxide (RuO₂). The sensormay be used for measuring the O₂ or the H₂S concentration. Details onthe monomers used in the sol-gel are not disclosed.

J. Mater. Chem. 2012, 22, 11720 shows a method in which two monomers(ETEOS and GPTMS) are used in the sol-gel. The monomers are separatelyreacted and methylimidazole is used to initiate the reaction of GPTMS.When the separately reacted monomers are mixed, the indicator moiety(HPTS) is added. Thus, a Lewis acid for initiating the reaction is notused and an indicator moiety (e.g. HPTS) is not covalently attached to asilane. Methods based on catalysis by methylimidazole may be inferior,as tests performed by the present inventors have shown thatmethylimidazole reacts and form fluorescent compounds, which areimmobilized in the sol-gel.

It is the purpose of the present invention to improve the porosity ofsol-gel materials for optical sensing, while at the same timemaintaining a high physical stability and a low auto-fluorescence. Ahigh porosity results in a short response time, which makes it possibleto react on a change faster.

SUMMARY

The present invention relates to a method for the production of asol-gel based matrix comprising the steps of:

a) providing a first alkoxysilane of the general formula:R¹—Si(OR²)₃

and a second alkoxysilane of the general formula:

R³—Si(OR²)₃

wherein

R¹ represents a straight or branched C₁-C₆ alkyl or C₂-C₆ alkenyl, aC₃-C₆ cycloalkyl, a C₁-C₆ aminoalkyl, a C₁-C₆ hydroxyalkyl, a C₁-C₆cyanoalkyl, a phenyl, a group of the formula —Y—(X—Y)_(n)H, wherein Yindependently is selected from straight or branched C₁-C₆ alkylene, X isa hetero atom or group selected among O, S, NH, and n is an integer of1-5,

or R¹ represents a C₁-C₆ alkyl substituted with a group Z,

wherein Z independently is selected form the group comprising hydrogen,cyano, halogen, hydroxy, nitro, amide C₁-C₂₄-alkyl, C₁-C₂₄-haloalkyl,C₂-C₂₄-alkenyl, C₂-C₂₄-alkynyl, aryl, C₁-C₂₄-alkoxy,C₁-C₂₄-alkylsulfonyl, amino, aminocarbonyl, aminothiocarbonyl,aminocarbonylamino, aminothiocarbonylamino, aminocarbonyloxy,aminosulfonyl, aminosulfonyloxy, aminosulfonylamino, amidino, carboxyl,carboxyl ester comprising a C₁-C₆ alkyl alcohol moiety, (carboxylester)amino comprising a C₁-C₆ alkyl alcohol moiety, (carboxyl ester)oxycomprising a C₁-C₆ alkyl alcohol moiety, sulfonyl, sulfonyloxy, thiol,thiocarbonyl, C₁-C₂₄-alkylthio, 5 or 6 membered heteroaryl, or a C₃-C₇cycloalkyl;

R² independently represents a straight or branched C₁-C₆ alkyl; and

R³ represents a linker chosen from a group of the formula—R⁴—(X—R⁴)_(n)—

wherein R⁴ independently is selected from straight or branched C₂-C₆alkylene, C₂-C₂₄-haloalkylene, X is a hetero atom or group selectedamong O, S, NH, and n is an integer of 0-12,

b) preparing a first sol-gel component by polymerisation of the firstalkoxysilane in the presence of an acid catalyst,

c) preparing a second sol-gel component by polymerisation of the secondalkoxysilane in the presence of an Lewis acid catalyst,

d) Mixing the first sol-gel component and the second sol-gel componentfor the preparation of a sol-gel based matrix.

It was discovered by the inventors that the use of a Lewis acid for thecatalysis of the second sol-gel component did not result in theformation of fluorescent compounds or other by-products, as was the casefor methylimidazole. Furthermore, the Lewis acid showed the addedpotential of being incorporated in the sol-gel, thus adding to theporosity.

In another aspect of the present invention an additional alkoxysilane isadded to step b) and/or c), said additional alkoxysilane being of theformula:R⁵—Si(OR²)₃

wherein R² is as defined above and R⁵ represents a group havingcovalently attached an indicator or reference dye.

While the present invention may work well in many applications with anindicator dye or reference dye non-covalently attached to the silanescaffold matrix a more durable sol-gel based matrix may be obtained byattaching the indicator or reference dye covalently to the matrix. Amore stable product may collect reliable data for prolonged time. Theadded physical stability may further broaden the application of thesensor incorporating the sol-gel based matrix to applications in whichthe indicator or reference dye may otherwise easily leak to the media.

The indicator dye or the reference dye may be attached to the silanematrix in a variety of ways. In a certain embodiment R⁵ is of thegeneral formula—R³—NH—C(═O)—X—R³-Q

wherein R³ is as defined above and independently selected, and Qrepresents an indicator and/or a reference dye.

The reference dye and/or the indicator dye can be selected from avariety of possibilities well known for the person skilled in the art.According to a certain aspect of the present invention Q is an indicatordye derived from 8-hydroxypyrene-1,3,6-trisulfonic acid (HPTS),fluorescein, or rhodamine B.

The type of reference dye is not particularly limited to a certain classof compounds. Thus, in an embodiment of the present invention Q in theabove formula is a reference dye derived from triangulenium compounds,acridinium compounds, ruthenium doped sol-gel particles, ruthenium-basedcompounds with α-diimine ligands, porphorin with Pt or Pd as the centralmetal atom, Ru(bpy)₂(dpp)Cl₂, Ru(bpy)₃C₁₂, a lanthanide containingcomplex, or polymeric metal containing structure.

According to the present invention a Lewis acid is used in thepolymerization of the second sol-gel component. Definitions of Lewisacids may vary from textbook to textbook. The IUPAC definition is “amolecular entity (and the corresponding chemical species) that is anelectron-pair acceptor and therefore able to react with a Lewis base toform a Lewis adduct, by sharing the electron pair furnished by the Lewisbase”. Usually, the Lewis base is ⁻OH present in the media. In a certainembodiment of the present invention a Lewis acid is a trigonal planarspecies, such as BF₃ or AlCl₃. Specific examples of Lewis acidsaccording to the present invention include TiCl₄, AlCl₃, and BF₃, orsolvates or etherates thereof.

The additional alkoxysilane may be added at any suitable point in timeduring the method. In a preferred aspect, the additional alkoxysilane isadded to first sol-gel component, the second sol-gel component or bothduring the preparation.

When an indicator dye as well as a reference dye is present it ispreferred that either the reference dye or the indicator dye is added tothe first sol-gel component of step b) and the other dye is added to thesecond sol-gel component of step c).

The first alkoxysilane may be selected in accordance with the formulaindicated above. Specifically, the first alkoxysilane is selected amongethyltriethoxysilane (ETEOS), methyltriethoxysilane (MTEOS),propyltriethoxysilane (PrTEOS), n-octyltriethoxysilane (n-octyl TEOS),methyltrimethoxysilane (MTMOS), aminopropyltrimethoxysilane (APTMOS),phenyltriethoxysilane (PhTEOS), and phenyl trimethoxysilane (PhTMOS). Incertain matrixes a first silane with a less bulky side groups may bepreferred to ensure high response times. Examples of such preferredfirst alkoxysilanes are ETEOS, MTEOS, PrTEOS, and MTMOS.

The second alkoxysilane may be selected in accordance with the formulaindicated above. Specifically, second alkoxysilane is selected among3-glycidoxypropyltrimethoxysilane (GPTMS).

The method described herein produces a sol-gel based matrix. The sol-gelbased matrix so produced is also part of the present invention.

The relative amount of the individual components of the sol-gel basedmatrix may be adjusted in accordance with the need and desiredproperties of the final product. In a certain aspect the amount in moleof first alkoxysilane to second alkoxysilane is in the range of 10:1 to1:10. Suitably, the amount of the first alkoxysilane to secondalkoxysilane is in the range of 5:1 to 1:5, such as 2:1 to 1:2,preferable around 1:1.

In one aspect, the invention relates to a composite comprising a layerof sol-gel based matrix and a platform comprising a microstructure area,wherein the sol-gel based matrix is attached to the microstructure area.In one embodiment, the composite comprises a sol-gel based matrixaccording to the invention.

The composite of the invention provides a fast response time for thedetection of analytes. The response of the composite may be detectableby detecting light or other electromagnetic radiation emitted by thesol-gel matrix, e.g. fluorescence and/or phosphorescence, and/or thelike.

The platform may comprise a plurality of microstructures, such as 2, 10,50, 100, 1000, or more microstructures. The microstructure may bearranged in an array measuring various analytes and concentrationsthereof.

For the purpose of the present description, the term microstructure arearefers to a structure having a plurality of micrometer-scale pillars.The plurality of micrometer-scale pillars may be depressions and/orprotrusions of a predetermined cross-sectional geometry, e.g.cylindrical or conical pillars. The microstructure may have a shapehaving an extent in at least one dimension, e.g. in two or even allthree dimensions, between 0.1 μm and 50 mm, e.g. between 1 and 20 mm,preferable between 5 and 10 mm.

The pillars may be cylindrical, cubic, or any other form. The pillarsmay be arranged in a pattern, e.g. a regular pattern, in a square orhexagonal grid. However, a random pattern of pillars may be used aswell. The pillars may have any size and shape. The pillars may bebetween 0.1 μm and 500 μm, preferably between 5 and 100 μm, morepreferable between 10 and 40 μm in height.

The distance or length between each pillar may be between 0.1 μm and 500μm, preferably between 5 and 100 μm, more preferable between 10 and 40μm. The width or diameter of the pillars may be between 2 and 100 μm,more preferable between 5 and 40 μm.

In a preferred embodiment the distance between each pillar is between 5and 40 μm, the height of the pillars are between 10 and 40 μm and thewidth of each pillar is between 5 and 40 μm. The pillars are preferablyarranged in a hexagonal geometry. An example of such preferredarrangement and geometry of the pillars in the microstructure in theplatform area is shown in FIG. 10. The advantage of this embodiment isthat it allows single step manufacturing of blown molded flask andinjection molded container parts with one or more microstructures and atthe same time is suited for attaching the sol-gel based matrix to themicrostructure because it is an optimal compromise between the rheologyof the plast/glass of the container and the ability to form a strongattachment with the sol-gel based matrix.

The microstructure may comprise a plurality of pillars in which thepillars, depressions and/or protrusions have different heights. Thedistance between the pillars, depressions and/or protrusions may bedifferent.

The microstructure may be made of any suitable material such as apolymer, a plastic, glass, etc. Examples of suitable materials includeinorganic materials, such as silicon, silicon oxides, silicon nitrides,III-V materials, such as, e.g., GaAs, AlAs, etc. Further examples ofsuitable materials include organic materials, such as, but not limitedto, SU-8, polymethylmethacrylate (PMMA), polycarbonate (PC), polystyrene(PS), TOPAS® (cyclic olefin copolymer), organically modified ceramics(ORMOCER®). The material may be optically transparent or reflective atthe used wavelengths of light or other electromagnetic radiation.

In one embodiment, the microstructure area comprises a plurality ofpillars having a height between 0.1 μm and 500 μm and a distance betweeneach pillar between 0.1 μm and 500 μm. The microstructure may also beapplied to a curved surface. However, irrespective of whether thesurface is curved or not, the shape of the pillars forming themicrostructure area may be designed such that the microstructure areaalso improves or even optimizes the extraction of the light from adeposited sol-gel based matrix material during use as an optical sensor.For example, when the microstructure is an multitude of pillars thathave a truncated-conical shape, the light emitted from a depositedsensor material may be directed to the optical sensing element throughreflections on the inner surfaces of the pillar.

In one embodiment, the layer of the sol-gel based matrix has a thicknesssmaller than the height of the microstructure or the height of thepillars. Thus the microstructure or the pillars of the microstructurepenetrates the layer of the sol-gel based matrix, thereby providingstability to the sol-gel based matrix. Thus, the attachment of thesol-gel based matrix to the microstructure is improved.

In another embodiment, the composite comprises one or more sol-gel basedmatrixes comprising indicator or reference dyes. If the composites ofthe invention comprise different reference and indicators dyes, it willbe possible to monitor one or more analytes and/or concentrationsthereof simultaneously. The use of the composites of the inventionreduces the amount of space required for the monitoring.

In yet another embodiment, the invention relates to an array of sol-gelbased matrixes attached to different areas on the microstructure area.In yet another embodiment, the plurality of sol-gel based matrixesincludes at least two sol-gel based matrixes having different indicatoror reference dyes.

A plurality of separate platform areas, e.g. a plurality of sol-gelbased matrixes on respective of sol-gel based matrixes areas, may beprovided; in particular the plurality of sol-gel based matrixes mayinclude at least two of sol-gel based matrixes having differentthickness of the respective layer of the sol-gel based matrixes. Hence,different properties, e.g. sensitivity, may be provided. Further,different layers of sol-gel based matrixes may be obtained by providingvariations in height/spacing profile of the microstructure.

This is particularly suitable for providing of sol-gel based matrixes onan inside surface of a container, e.g. a container for accommodating afluid, e.g. a bottle, a tube, a flask, a bag, a microtitre plate, and/orthe like. The surface may be planar or have a curvature in one or moredirections. The deposited of sol-gel based matrixes may thus be used tosense e.g. analytes or other properties of a medium (e.g. a fluid) incontact with the surface, e.g. a medium inside a container or laboratoryconsumable. In particular, the sol-gel based matrixes may be read bydetecting light emitted from the of sol-gel based matrixes responsive tothe detected property. The light emission may be detected through thewall of a container by a detector placed outside the container orlaboratory consumable.

In yet another embodiment, platform of the composite is an inner surfaceof a container or conduit for transporting a fluid. In yet anotherembodiment, the container comprises an opening and cylindrical ortapered sides, and is closed opposite to the opening. In yet anotherembodiment, the platform is an inner surface of a disposable containerfor transporting a fluid.

The composite may amongst other without being limited be deposited inand/or constitute a part of open or closed containers, or laboratoryvessels, dedicated sensing equipments and laboratory consumables to actas a build-in sensor for analytes such as pH, dissolved oxygen (DO),conductivity, etc.

The composite may be deposited and constitute a part of open or closedcontainers, or laboratory vessels to yield a sensor spot, which may becircular or take any other form. The amount deposited may be 1 ul, 10ul, 100 ul or even more. Any number of sensor spots can be deposited ina piece of equipment, consumable or vessel. The size of the spot may be100 um², 1 mm², 10 mm², 100 mm², 1 cm², 10 cm², 100 cm² or even more.

The container or laboratory consumable may be made of glass,polystyrene, polycarbonate or any polymer or composite materialtransparent to light, preferable green and red light (450 nm to 800 nm).

In one aspect, the invention relates to the use of a composite accordingto the invention for monitoring of a bioculture. The environment anddevelopment of the bioculture may be followed, periodically orcontinuously, e.g. by detecting light emitted from the composite orsensor.

Thus, the sol-gel based matrixes and composites of the invention may beused as integrated sensors or props, thereby reducing the risk ofcontamination as these can be read from the outside of the containerand/or laboratory vessels.

In one aspect, the invention relates to a method for the preparation ofa composite, comprising

-   -   providing a platform with a predetermined microstructure, and    -   depositing a layer of sol-gel based matrix on at least a part of        the microstructured area.

Methods for deposition of sensor material, such as a sol-gel basedmatrix, on a homogeneous layer in a well-defined region of a surface arewell known in the art, Quéré D 2008, Annu. Rev. Mater. Res. 38 71-99. Adrop of liquid material that is deposited on the microstructured areawill spread, guided by the structures of the pillars, to homogeneouslyfill the volume between the pillars.

Generally, a sol-gel process, also known as chemical solutiondeposition, is a wet-chemical technique suitable for the fabrication ofmaterials, e.g. a metal oxide, or glass, starting from a chemicalsolution acting as a precursor for an integrated network, or gel, ofdiscrete particles or network polymers. The process typically includesthe removal of liquid after deposition of the precursor on the surface,e.g. by sedimentation and removal of the remaining solvent, by drying,and/or the like. Afterwards, a thermal treatment, or firing process, maybe employed.

Microstructuring of e.g. the inside of blow-molded plastic containersmay be performed using step-and-stamp imprint lithography (Haatainen Tand Ahopelto J 2003 Phys. Scr. 67 357), and for plastic componentsproduced by injection molding, microstructures can be integrateddirectly in the mold (Utko P, Persson F, Kristensen A and Larsen N B2011 Lab Chip 11 303-8). Both of these fabrication methods are suitedfor large-scale industrial production.

Spreading of the liquid is governed by the geometry of themicrostructures and the thickness of the deposited film is determined bythe height of the pillars and is thus independent of the volume of thedeposited drop. This enables easy and reproducible deposits of spots ofthe sol-gel based matrix of precise thickness to be made surfaces, suchas metallic and plastic surfaces.

Spreading of the sol-gel based matrix enables direct, controlleddeposition of spots of the sensor material inside containers, and itsimplifies the fabrication of optical sensors in disposable lab ware.

The term immobilising is intended to refer to any process for causingdeposited layer to remain fixed as an integral layer covering andattached to at least a portion of the deposition area. The immobilisingor fixation of the deposited sol-gel based matrix may be performed by avariety of techniques, e.g. by curing, hardening the deposited liquid,by evaporation of a solvent, by a sedimentation process, by covering thedeposited sol-gel based matrix by a sealing layer, e.g. a foil, membraneetc. and/or a combination of the above. For example, the depositedsol-gel based matrix may be immobilized on the surface by solventevaporation, by cross-linking due light exposure, exposure by otherforms of electromagnetic radiation, and/or by thermal treatment, and/orby any other suitable curing process. Materials which remain liquidafter deposition on the microstructures are also a possibility; suchmaterials may be immobilized by depositing a cover layer, e.g. amembrane, on top of the deposited sol-gel based matrix. Hence, theprocess results in a composite layered product in which themicrostructure area and a layer of deposited sol-gel based matrix areefficiently bonded to each other.

In some embodiments, e.g. due to the removal of the liquid, e.g. bysolvent evaporation, the immobilising process may cause a volumereduction of the immobilised sol-gel based matrix compared to theinitially deposited volume. This may result in the immobilised sol-gelbased matrix having a local thickness, measured in the spaces betweenprotrusions of the microstructure, smaller than the height of themicrostructure. This may also result in a convex upper surface of theimmobilised deposited sensor material. In that case the optical paththrough the film on vertical side walls is much larger than thethickness of the film that an analyte has to diffuse through, and alarger surface is achieved, thus reducing the response time of thesensor.

In one embodiment of the invention, at least a part of the sol-gel basedmatrix is immobilised resulting in an immobilised layer of sol-gel basedmatrix attached to the surface of the microstructure area. In anotherembodiment of the invention, the immobilised layer of sol-gel basedmatrix has a thickness smaller than the height of the microstructure. Inyet another embodiment of the invention, the microstructured area isprepared by a process chosen from injection molding, hot embossing,laser microstructuring, micromachining, chemical etching, photoresistlayer structuring.

DRAWINGS

FIG. 1 shows the general preparation steps for deposition of sensormaterial on a substrate,

FIG. 2 shows the leakage over time of sensor spots.

FIG. 3 shows the development over time for the ratiometric signal infour different buffer solutions,

FIG. 4 shows the ratiometric responses; FIG. 4a shows TMAAcr-4immobilised in the GPTMS-ETEOS matrix via lipophilic entrapment, andFIG. 4b shows TMAAcr-6 immobilised in the GPTMS-ETEOS matrix viacovalent entrapment.

FIG. 5 shows the emission spectra of the sensors in action; FIG. 5ashows the emission spectra of a GPTMS-ETEOS matrix with TMAAcr-4 andDMQA-1 lipophilic entrapped in the matrix, and FIG. 5b shows theemission spectra of the GPTMS-ETEOS matrix with TMAAcr-6 covalently andDMQA-1 lipophilic entrapped in the GPTMS-ETEOS matrix.

FIG. 6 shows the response times of the pH active dye DAOTA-2; FIG. 6ashows the response time in PhTEOS-GPTMS matrix, FIG. 6b shows theresponse time for ETEOS-GPTMS matrix, and FIG. 6c shows the responsetime for the PrTEOS-GPTMS matrix.

FIG. 7 discloses the response time of the pH active dye DAOTA-2 in anETEOS-GPTMS matrix, compared to a matrix PVA and PEG-DA.

FIG. 8 discloses the intensity ratio of lipophil bounded DQMA and aruthenium kompleks (Tris(4,7-diphenyl-1, 10-phenanthroline)ruthenium(II) bis(hexafluorophosphate) kompleks CAS Nummer 123148-15-2) measuredby ratiometic titration (I(Ru)/I(DMQA)) in aqueous solutions havingdifferent oxygen concentrations. The measurements are determined with anoptical DO electrode from Mettler-Toledo.

FIG. 9. Example of laboratory consumables comprising a sol-gel matrixaccording to the invention.

FIG. 10 shows a preferred arrangement and geometry of the microstructurein the platform area.

DETAILED DESCRIPTION

The sol-gel based matrix is usually deposited on a substrate as a partof a sensor. The substrate is generally selected to optimise the abilityof the sol-gel to form an immobilized attachment to the substrate.Suitable substrates include glass, plastics, ceramics, and polymers.Suitable polymer substrates include polycarbonates, acrylics such aspoly(methyl methacrylate), acrylonitrile-butadiene-styrene copolymer,polyvinylchloride, polyethylene, polypropylene, polystyrene,polyurethanes, silicones, and vinylidene fluoride-hexafluoropropylenecopolymer.

The first sol-gel component is prepared by polymerisation of the firstalkoxysilane defined above in the presence of an acid catalyst. The acidcatalyst may be any suitable acid, such as an inorganic or organic acid.Suitable inorganic acids include hydrochloric acid (HCl), nitric acid(HNO₃), phosphoric acid (H₃PO₄), sulphuric acid (H₂SO₄), hydrofluoricacid (HF), hydrobromic acid (HBr) and perchloric acid (HClO₄). Apreferred inorganic acid is hydrochloric acid. Suitable organic acidsinclude lactic acid, acetic acid, formic acid, citric acid, oxalic acid,and malic acid. Furthermore, the acid catalyst may be any combination ofthe above compounds.

To be suitable, the acid chosen must be able to hydrolyse the firstalkoxysilane under the acidic conditions. The hydrolysis initiates thepolymeric condensation reaction upon formation of a polymer siliconoxide network.

The procedure for the preparation of the first sol-gel componentgenerally include that the first alkoxysilane is dissolved in an organicsolvent, usually an alcohol like ethanol prior to the addition of theacid catalyst. The amounts in mole of acid are generally at the samelevel or lower as the molar amount of the first alkoxysilane. Themixture of first alkoxysilane, organic solvent and acid catalyst is leftuntil the reaction is completed. The reaction time may be several days.

The second sol-gel component is prepared by either dissolving the secondalkoxysilane in a solvent before the addition of the Lewis acid catalystor by mixing the alkoxysilane and the Lewis acid and then adding thesolvent. The molar amount of Lewis acid catalyst is generally lower thanthe molar amount of the second alkoxysilane. In a preferred embodimentthe molar amount of Lewis acid to second alkoxysilane is 1:2, such as1:3, preferably 1:4. The solvent is usually an alcohol like ethanol butmay be chosen among various solvents assumed by the skilled person to beinert under the conditions.

The Lewis acid is believed to attack the epoxy ring of the secondalkoxysilane whereby a secondary carbocation is formed. Thisintermediate carbocation can then react with another molecule in thepolymerisation process. The amount and the type of second alkoxysilaneshould be chosen so as to be able to participate in the intendedchemical reaction within a reasonable time. The formation of the secondsol-gel component normally proceeds much faster than the formation ofthe first sol-gel component. A typical reaction time for the secondsol-gel component is between 10 min and 3 hours. After the reaction thesecond sol-gel component is typically allowed to rest for a few hours.

After the two sol-gel components have been prepared separately, they aremixed. Typically, the molar amount of the first sol-gel component to thesecond sol-gel component is in the range of 5:1 to 1:5, such as 3:1 to1:3, typically 2:1 to 1:2, and suitably approximately 1:1.

If the sol-gel matrix is used for sensing, an indicator and/or referencedye may be incorporated in to the matrix by a number of methods toobtain either a non-covalent or a covalent attachment. If a non-covalentattachment is used it is preferred to anchor the dye in some way to thematrix to avoid excessive leakage. A preferred anchoring method is theso-called lipophilic entrapment, according to which the dye core isprovided with one or more lipophilic linkers. The lipophilic linkerswill engage with the lipophilic environment of the network formed by thesol-gel components and thereby retard the leakage. In a preferred methodthe dye core provided with one or more lipophilic linkers is addedeither to one or both of the sol-gel components or to the mixture of thefirst and the second sol-gel component. To ensure a sufficientmaturation of the mixture it may be kept for 1 hour to 7 days before itis deposited on the substrate and cured.

A covalent attachment of the dye is possible by linking the dye to oneof the monomers before polymerisation. In a preferred method, anadditional alkoxysilane is prepared as a derivative of the firstalkoxysilane by attaching the dye thereto. The additional alkoxysilanemay be incorporated into either the first sol-gel component or thesecond sol-gel component. In a preferred aspect the first or secondalkoxysilane is allowed to polymerise a short time, such as at least 15minutes, before the further alkoxysilane is added to avoid endpositioning.

The mixture of the first sol-gel component and the second sol-gelcomponent may be allowed to mature before the deposition on a suitablesubstrate. The substrate is generally transparent at the wavelength usedfor monitoring the emitted light. The amount of the mixture used fordeposition varies in dependence of the purpose and geometry of thesensor. In a certain aspect the amount is 100 μl or less, such as 50 μlor less, suitably 20 μl or less. The deposition may be referred toherein as a “spot”.

The addition of the mixture to the substrate may be allowed deliberatelyto solidify or the added amount of mixture may be spread on thesubstrate to form a film with an essentially uniform thickness. Afterthe deposition of the mixture on the substrate it is cured. The curingmay be performed in a number of ways, including heating at elevatedtemperatures so as to form a solid film attached to the substrate. Thetemperature of the curing is suitably 70° C. or above, such as 90° C. orabove, and suitably 100° C. or above. Usually, the curing temperaturedoes not exceed 150° C. to avoid degradation of the materials, i.e. tomaintain the porous three dimensional polymer networks, which allow forfast diffusion of the analyte, such as a proton. The relativelyunhindered diffusion of the analyte in the porous network is believed tobe the reason for the observed fast response time.

The research reported herein suggests that covalent attachment of thedye to the polymer network is preferred when a long-time stability is ofimportance. Even when the dyes are provided with lipophilic linkers toretard the leakage from the film, the leakage is still too high for aproduct stabile over a longer time period to be obtained. For short-timeuse, such as in non-reusable sensors, non-covalently attached dyes maybe acceptable.

An aspect of the invention relates to the manufacturing of a containeror laboratory equipment with a composite, i.e. a container or laboratoryequipment respectively comprising one or more platforms. Particularlysuited laboratory equipment is Erlenmeyer flasks, beaker glasses, tissueculture flasks, tissue culture dishes, tissue culture plates and storagesystems. Examples of laborative equipments comprising the composite ofthe invention are shown on FIG. 9.

EXAMPLES

Methods and Materials

Compounds were used as received. Sol-gel monomers were purchased fromSigma-Aldrich. Sol-gel catalysts were purchased from Sigma-Aldrich andused as received. Solvents used were analytical or HPLC grade. Anelectronically controlled oven was used to cure the ORMOSIL thin-films.

Synthesis

The synthesis of compounds 1.BF₄ and 2.PF6 are reported elsewhere.¹⁸

General Preparation of Tetramethoxyamino-Acridinium (TMAAcr)

2 (162 mg, 0.23 mmol) was dissolved in 15 ml acetonitrile andn-octylamine (26 ml, 0.14 mmol) was added to the solution. The reactionmixture was heated to slight reflux temperature and stirred in 5 h. Thereaction mixture was allowed to cool down when the color of the mixturehad changed from blue to red-brown and MALDI-TOF analysis indicated thata mass corresponding to that of the starting material was not presentany more. The reaction mixture was washed with heptane (3×50 ml). Thecrude product was isolated by evaporation and recrystallized fromethanol, and the product was washed with ether and heptane severaltimes. The product was isolated as a red-purple powder, which wasmetallic-green when filtered.

General Approach to Activate TMAAcr for Covalent Attachment

TMAAcr (100 mg, 0.11 mmol) was dissolved in 20 ml acetonitrile and thentriethoxy(3-isocyanatopropyl)silane (1.1 ml, 0.45 mmol) was addeddropwise using a syringe at room temperature. The mixture was stirredfor 1 h, when MALDI-TOF analysis indicated that 9 was not present. Thereaction mixture was washed with heptane (3×50 ml) and then theacetonitrile phase was mixed with a 0.2 M KPF₆ solution. The slurry wasstirred for 20 min and then gently filtered. The precipitate was washedwith water several times. The product was dissolved in dichloromethanethrough the filter and the non-dissolved solid in the filter wasdiscarded. The product is collected by removal of the solvent yieldingmetallic-green flakes.

General Preparation of Dimethoxyquinacridinium (DMQA)

A primary amine (20 eq, 40 mmol) was added to a solution of DMB₃C.BF₄ ¹⁹in NMP (1.0 g, 2 mmol in 8 mL). The solution was warmed to 140° C. for10-20 minutes (the degree of reaction is followed by MALDI-TOF massspectroscopy). After cooling to RT the reaction mixture was poured on to0.2 M KPF₄(aq) (200 mL). The precipitate was collected, washed anddried. The crude can be recrystallized from methanol, reprecipitatedfrom dichloromethane with ethylacetate or reprecipitated fromacetonitrile with ether depending on the how lipophile the side chainsare.

General Approach to Activate DMQA for Covalent Attachment

DMAQ (70 mg, 0.143 mmol) was dissolved in 8 ml anhydrous acetonitrileand then 3-(triethoxysilane)propyl isocyanate (cold, 100 ul, d=0.999g/ml, 0,404 mmol) was added. The flask was fitted with a stopper andstirred at room temperature for 4 h. After 4 h MALDI-TOF analysisindicated that the reaction mixture only contained starting material.Then excess of isocyanate (1 ml) was added together with approx. 1 ml oftriethylamine. The mixture was heated to 65° C. and stirred for 1.5 h.Then MALDI-TOF analysis indicated that the reaction mixture contained acompound with a mass of 649 m/z, which is the mass of the desiredproduct and no mass corresponding to that of the starting material waspresent. The reaction mixture was washed (still warm) with heptane (2×50ml) and then dried over MgSO₄ for 10 min. The solvent was removed byevaporation at 50° C. in vacuum and the crude product was dissolved in aminimum of CH₂Cl₂ and then diethyl ether (200 ml) was added and a greenprecipitate was allowed to form. The dark product was collected anddried in vacuum over KOH overnight.

Spectroscopy

Emission spectroscopy was performed in front-face set-up for sensor spotsamples and in a conventional L-shape set-up for measurements insolution. A Perkin-Elmer LS50B and a Horiba Fluorolog 3 were usedinterchangeably. Intensity based sensor measurements were only performedon the LS50B platform. Fluorescence lifetime based sensor measurementswere only performed on the Fluorolog 3. Absorption spectroscopy wasperformed on a Perkin Elmer Lambda 1050, with integrating sphere (forsensor spots) and with a 3-detector module for solution samples.

Sol-Gel Preparation

The procedure includes preparation of two separate gel components of theorganic modified silanes: Ethyltriethoxysilane (ETEOS) or a similaralkyl or aryl trialkoxy silane (XTEOS) and3-(glycidoxy)propyltrimethoxysilane (GPTMS). All the differentpreparations and combinations are compiled in table 1, and the detailedprocedures are as follows.

TABLE 1 The different compositions of sol-gels tested in this work;variations can be seen in the alkyltrialkoxy silane part, the Lewisacid, and the dye additives. The pKa of the resulting sensor isincluded. Entry Monomer 1 Monomer 2 Catalyst Dye 1 Dye 2 pKa 1 GPTMSETEOS BF₃ TMAAcr-1 — 3.8 2 GPTMS ETEOS BF₃ TMARh — 1.1 3 GPTMS ETEOS¹BF₃ TMAAcr-3 — 2.6 4 GPTMS ETEOS² BF₃ TMAAcr-3 — 3.1 5 GPTMS ETEOS BF₃TMAAcr-4 DMQA-1 4.9 6 GPTMS ETEOS¹ BF₃ TMAAcr-6 DMQA-1 4.8 7 GPTMS ETEOSBF₃ DAOTA-1 DMQA-2 6.5 8 GPTMS ETEOS BF₃ DAOTA-2 DMQA-2 6.5 9 GPTMSPrTEOS BF₃ DAOTA-2 DMQA-2 6.5 10 GPTMS PhTEOS BF₃ DAOTA-2 DMQA-2 6.7 11GPTMS ETEOS TiCl₄ DAOTA-2 DMQA-2 — 12 GPTMS ETEOS AlCl₃ DAOTA-2 DMQA-2 —¹Dye 6 pre-mixed with ETEOS component, ²Dye 6 pre-mixed with GPTMScomponent.

ETEOS

The ETEOS gel component is prepared from polymerization of the siliconnetwork under acidic conditions. ETEOS is hydrolysed under acidicconditions, which initiates a polymeric condensation reaction uponformation of a polymer silicon oxide network. The presented procedure isan equivalent to the procedure reported by Wencel et al.^(10, 11)

Procedure for preparation of ETEOS gel component: 5 ml ETEOS (0.02 mol)is dissolved in 8 ml absolute ethanol (0.14 mol) upon stirring.Hereafter, 1.6 ml of 0.1 M HCl solution (0.16 mmol) is added dropwise.This mixture is then left on a stirring table for a minimum of 7 days toallow the polymerization process to proceed.

GPTMS Gel Component.

The GPTMS gel component is prepared from polymerization of the organiclinker using a Lewis acid as initiator. In this procedure we use borontrifluoride diethyletherate as the Lewis acid. The Lewis acid attacksthe epoxy ring that allows for ring opening of the epoxy ring uponformation of a secondary carbocation. This intermediate carbocation canthen react with another GPTMS molecule, initiating a polymerizationreaction. Due to the acidic environment a polymerization of the siliconnetwork equivalent to that described for the ETEOS component willproceed alongside.

Procedure for preparation of GPTMS gel component: 6 ml of GPTMS (0.027mol) is mixed with 11 ml of absolute ethanol (0.19 mol) upon stirring.Then 0.75 ml of cold borontrifluoride diethyletherat (BF₃.O(CH₂CH₃)₂,5.8 mmol) is added dropwise. The mixture is left with stirring for 30min in a sealed container until the temperature of the mixture hasdropped to room temperature. After 30 min 2 ml of MilliQ water (0.11mol) is added to the solution. The resulting mixture was left withstirring for 4 h.

When the two gel components have been prepared they are mixed in 1:1molar ratio and left for a minimum of 3 days to allow the networks tomix. This is referred to as the GPTMS-ETEOS mixture.

GPTMS-ETEOS Mixture

When the GPTMS and ETEOS components have been prepared they are mixed toobtain a 1:1 molar ratio (1.1 ml GPTMS+1 ml ETEOS) and the dyes areadded in order to obtain a concentration of approx. 0.1 mM. Theresulting mixture is then allowed to further mix for a minimum of 3days.

The GPTMS-ETEOS mixture with the dye entrapped can now be deposited ontoa glass or plastic surface. When deposited it has to be cured at 110degrees for 3-4 h. The result is a porous and transparent matrix.

XTEOS Variations

A procedure analogous to that for the ETEOS Gel component describedabove used to make XTEOS gel components, with X=Pr and Ph.

Preparation of XTEOS Gel Components

X=Phenyl (Ph): Phenyltriethoxyilane (PhTEOS, 10 ml, M=240.14 g/mol,d=0.996 g/ml, 0.041 mol) and absolute ethanol (15 ml, d=0.789 g/ml, 0.26mol) was mixed and the freshly prepared 0.1 M HCl solution (2.8 ml, 0.28mmol) was added. The solution was stirred for 15 min in the sealed vial,and then left at a vibration table for 20 days in the dark at roomtemperature.

X=Propyl (Pr): Propyltriethoxyilane (PrTEOS, 10 ml, M=206.13 g/mol,d=0.892 g/ml, 0.043 mmol) and absolute ethanol (16 ml, d=0.789 g/ml,0.27 mol) was mixed and then freshly prepared 0.1 M HCl solution (3.2ml, 0.32 mmol) was added. The solution was stirred for 15 min in thesealed vial, and then left at a vibration table for 20 days in the darkat room temperature.

Lipophilic Entrapment

In the lipophilic entrapment method the dyes in entrapped in theGPTMS-ETEOS network requires that the dye has one or several lipophiliclinker(s) attached to the dye to prevent leakage from the resultingmatrix material.

General Procedure for Lipophilic Entrapment of Dyes

The ETEOS and GPTMS gel components are prepared and mixed as describedabove with the addition of the dye such that a final concentration of0.1 mM is obtained. The resulting GPTMS-ETEOS-dye mixture is then leftat a stirring table for at least 3 days before deposition and curing at110° C. for 3-4 hours.

Covalent Method:

This procedure requires that the dye has been activated by linking to atrialkoxysilane group that can mix into the silicon network of eitherthe ETEOS or GPTMS gels.

General Procedure for Covalent Entrapment of Dyes into the GPTMS-ETEOSMatrix

The ETEOS and GPTMS gel components are prepared and mixed as describedabove, with the exception that the silane functionalized dye is mixedinto the either the ETEOS or the GPTMS gel component after 1 h aftermixing of the materials described to mix the ETEOS or the GPTMS gelcomponents. The GPTMS and ETEOS components are left for polymerizationreaction time described in the general procedure. The two components arethen mixed in the described 1:1 molar ratio and left at a stirring tablefor no less than 3 days. The dye should be added in an amount so that afinal concentration of 0.1 mM of dye is obtained in the finalGPTMS-ETEOS mixture. The resulting GPTMS-ETEOS-dye mixture is thendeposited and cured at 110° C. for 3-4 hours.

Fabrication of Sensor-Spots

The sensor spots were drop coated on a glass or polycarbonate substrateand then cured. The substrate material appears to be inconsequential aslong as thin films can be prepared. For comparison sensor spots wereprepared from direct incorporation of the dyes in PVA (from 10% w/wsolutions in water) which were subsequently drop coated on glass. PEG-DAhydrogel with dye entrapped was prepared by mixing PEG-DA (Mn=700) andethanol in a 1:1 v/v ratio and then the dye was added to obtain 1 mM.Then a catalytic amount of a solution of2,2′-azobis(2-methylpropionitrile) in CH₂Cl₂ (25 mg/ml) was added. Themixture was spread out on a petri dish, the dish was equipped with aglass lid, and the mixture was baked in the oven at 110° C. for 1 h. Athin piece of the resulting hydrogel was immobilized on a clean glassslide using double-sided tape and the regular tape.

Titrations

To perform titrations rapidly a set-up employing an epi-fluorescencemicroscopy equipped with a halogen light source and an Ocean Opticsspectrometer for detection. The sensor spot was attached to a homemadeholder, which kept the spot in place in a large chamber filled withwater, where pH was externally monitored with a pH meter. Alternativelythe sensor spot was affixed on the wall of a cuvette and the titrationwas performed in a Perkin Elmer LS50B, controlling the pH betweenmeasurements.

Stability Testing

The photostability was followed by constant illumination of the sensorspot with wavelength selected light from a xenon lamp. The physicalstability was tested by immersing the sensor spot in low or high pHaqueous solution, and monitoring the fluorescence from the solution.

Response Analysis

The signal from the sensor is monitored after inducing a significant(more than 4 pH units) jump in pH. The time it takes to obtain a full(100%) and partial (90%) response, compared to the equilibrium signal isrecorded.

FIG. 1 shows the general preparation of sensor spots.

Results

The tested sensors are prepared as illustrated in FIG. 1, on glass andpolycarbonate substrates. The five components are mixed in a fashionthat allows for the formation of a porous covalently linked 3D polymernetwork, which allows for fast diffusion of protons.

Scheme 2 shows the structure of the pH-responsive and the reference dyesused in this study. The pKa values of the resulting sol-gel basedsensors are compiled in table 1. Cursory inspections of the structures,which are physically immobilized in the sol-gel show that a long alkylchain is required to prevent leakage, while the molecules covalentlylinked to the matrix can have either a long or a short linker.

Stability

TABLE 2 Leaking of 5(6)-carboxyfluorescein (CF), DMQA-2, DAOTA-1, and6-stearamido-fluorescein (AF18) from the ETEOS-GPTMS matrix given asfluorescence intensity measured from a PBS solution at pH 7 surroundinga glass slide coated with ETEOS- GPTMS-dye matrix using maximum sizedslit widths at the emission and excitation sites of the spectrometer.Dye Intensity (a.u.) Leaking Period pH pK_(a) CF >>800 2 h 7.0 6.5DMQA-2 0 15 h 7.0 — DAOTA-1 80 15 h 7.0 6.5 AFC18 100 4 d 7.0 6.5

FIG. 2 shows leakage over time of sensor spots: non-bound5(6)-carboxyfluorescein (plus-signs), covalently bound DAOTA-1(crosses), and covalently bound DMQA-2 (dots).

FIG. 2 shows the performance in leakage studies, against the performanceof molecules without anchoring groups, and the data are collected intable 2. Leaking of the dyes entrapped or bound to the matrix wasinvestigated by measuring the emission intensity from a PBS solution atpH 7.0 surrounding a non-bound dye (5(6)-carboxy fluorescein, CF),covalently bound (DMQA-2 and DAOTA-1) using the largest possible slitwidths on the excitation and emission sites of the spectrometer and anexcitation wavelength of 450 nm, these data are shown in FIG. 2. Whilethe physically bound dye and 6-stearamido-fluorescein (AF18) was alsotested, we did not record the transient curve. All the leakage data iscompiled in table 2. The results reveal that DAOTA-1 leaked to a smallextend, which we, based on NMR data, can assign to a fraction ofun-linked dye in the ETEOS-GPTMS matrix, this issue has previously beenreported for fluorescein, which was only partially activated. Thecompound DMQA-2 could based on NMR data be shown to be 100% activatedand did as a consequence not show any leakage. This shows that effectivebinding can indeed be obtained in the ETEOS-GPTMS matrix and leakage canbe avoided completely by fully activating the dye for polymerization.The unbound CF showed extensive leakage and the data in table 2 isobtained using half the sizes of the slit widths as those used forDMQA-2 and DAOTA-1.

To evaluate the photostability of the sensor we performed a 16-hourscan, see FIG. 3. No perceivable slope of the curves could be seen inthis time interval, which proves that this system has a very highlong-term stability under constant irradiation.

FIG. 3 shows the development in the ratiometric signal in four differentbuffer solutions at pH 3 during 16 h of irradiation at 525 nm of aDAOTA/DMQA based sensor.

Sensor Action

The performance of the sensors is shown as titration curves in FIG. 4.The spectra behind the titration curves are shown in FIG. 5. It is clearthat a pH-dependent sensor action is achieved for these two sensorsystems. For the examples given in FIGS. 4 and 5 the pKa values are ˜5,the data for all prepared sensors are compiled in table 1, sensors witha pK_(a) from 1.1 to 6.7 was made.

FIG. 4a shows the ratiometric pH response of TMAAcr-4 immobilized inGPTMS-ETEOS matrix via lipophilic entrapment. FIG. 4b shows the pHresponse of TMAAcr-6 immobilized in the GPTMS-ETEOS matrix via covalententrapment. The pK_(a) values of TMAAcr-4 and TMAAcr-6 are determined to4.9 (lipophilic entrapment) and 4.8 (covalent entrapment).

FIG. 5 shows spectra of the sensors in action. FIG. 5a shows theemission spectra of a GPTMS-ETEOS matrix with TMAAcr-4 and DMQA-1lipophilic entrapped in the GPTMS-ETEOS matrix at different pH valuesbetween 3 (black) and 7.5 (red). FIG. 5b shows emission spectra of aGPTMS-ETEOS matrix with TMAAcr-6 covalently and DMQA-1 lipophilicentrapped in the GPTMS-ETEOS matrix at different pH values between 2(black) and 7.5 (red). Excitation at 475 nm±25 nm.

In order to evaluate the response time the temporal evolution of thedetected signal (intensity ratio) was monitored, when the sensor wasmonitoring a solution where the pH was changed drastically as well asmoderately. FIG. 6 shows the result, each panel shows the response ofdifferent matrices. It is clear that the response of the Lewis acidcatalyzed sol-gel is much faster than the others tested. To highlightthe differences an overlay is shown in FIG. 7. All the data are compiledin table 3. The alkyltrialkoxy-GPTMS matrixes have by far the fastestresponse times, showing some hysteresis, with a response going from highpH to low pH of ˜10 s and going from low pH to high pH of ˜20 s.Propyltrialkoxy silane derived matrices are faster responding than theethyltrialkoxy silane derived matrices when the signal level of 90% isconsidered, while the full response occur on a similar timescale forboth matrices.

FIG. 6 shows the response time of pH-active dye DAOTA-2 in aPhTEOS-GPTMS (FIG. 6a ), an ETEOS-GPTMS (FIG. 6b ) and PrTEOS-GPTMS(FIG. 6c ) matrices. High intensity: Low pH (<2). Low intensity: High pH(>10).

FIG. 7 shows the response time of pH active dye DAOTA-2 in anETEOS-GPTMS (red), PVA (blue) and PEG-DA (green) matrix. High intensity:Low pH (<2). Low intensity: High pH (>10).

TABLE 3 The response times (t₉₀ and t₁₀₀) given in seconds (s) of theETEOS-GPTMS, PrTEOS-GPTMS, and PhTEOS-GPTMS matrices with of thepH-active dye DAOTA-2 incorporated, and the response times of PVA filmand PEG-DA hydrogel with the pH-active dye TMAAcr-4 incorporated. H-Lrefers to the response time going from high (H) pH (>10) to a low (L) pH(<2) value, L-H has the opposite meaning. Numbers in parentheses referto response times measured in the ETEOS-GPTMS matrix with the dyesDAOTA-1 and DMQA-2 covalently bound. t₉₀ (H- t₁₀₀ (H- t₉₀ (L- t₁₀₀ (L-Matrix Dye L)/s L)/s H)/s H)/s PhTEOS- DAOTA-2 59 171 108 271 GPTMSETEOS- DAOTA-2 9 (10) 24 (30) 19 (23) 40 (47) GPTMS (DAOTA-1 DMQA-2)PrTEOS- DAOTA-2 6 34 7 31 GPTMS PVA TMAAcr-4 6 50 25 55 PEG-DA TMAAcr-440 98 192 262

CONCLUSION

We have shown that our system has a shorter or comparable response timethan what was previously reported and a high degree of photostability.Furthermore, with this sensor we have solved the leaking issue, usingeither covalent attachment or lipophilic entrapment of the activecomponents. We have also shown that the activation of the activecomponent is important in making leakage free film.

REFERENCES AND FOOTNOTES

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What is claimed is:
 1. A sol-gel matrix comprising: a first polymercomponent prepared from polymerization of a first alkoxysilane of thegeneral formula R¹—Si(OR²)₃ and an additional alkoxysilane of theformula R⁵—Si(OR²)₃, a second sol-gel component comprising a Lewis acidand a second polymer component prepared from Lewis acid catalyzedpolymerization of a second alkoxysilane of the general formula

wherein R¹ is selected from the group consisting of a straight andbranched C₁-C₆ alkyl, a C₂-C₆ alkenyl, a C₃-C₆ cycloalkyl, a C₁-C₆aminoalkyl, a C₁-C₆ hydroxyalkyl, a C₁-C₆ cyanoalkyl, a phenyl, and agroup of the formula —Y—(X—Y)_(n)H, with Y being independently selectedfrom the group consisting of straight and branched C₁-C₆ alkylene, Xbeing a hetero atom or group selected from the group consisting of O, S,and NH, and n being an integer of 1-5, or R¹ represents a C₁-C₆ alkylsubstituted with a group Z, with Z being independently selected form thegroup consisting of hydrogen, cyano, halogen, hydroxy, nitro, amideC₁-C₂₄-alkyl, C₁-C₂₄-haloalkyl, C₂-C₂₄-alkenyl, C₂-C₂₄-alkynyl, aryl,C₁-C₂₄-alkoxy, C₁-C₂₄-alkylsulfonyl, amino, aminocarbonyl,aminothiocarbonyl, aminocarbonylamino, aminothiocarbonylamino,aminocarbonyloxy, aminosulfonyl, aminosulfonyloxy, aminosulfonylamino,amidino, carboxyl, carboxyl ester comprising a C₁-C₆ alkyl alcoholmoiety, (carboxyl ester)amino comprising a C₁-C₆ alkyl alcohol moiety,(carboxyl ester)oxy comprising a C₁-C₆ alkyl alcohol moiety, sulfonyl,sulfonyloxy, thiol, thiocarbonyl, C₁-C₂₄-alkylthio, 5 or 6 memberedheteroaryl, and a C₃-C₇ cycloalkyl; R² independently represents astraight or branched C₁-C₆ alkyl; R³ represents a linker selected from agroup of the formula —R⁴—(X—R⁴)₀₋₁₂—, wherein R⁴ is independentlyselected from straight or branched C₂-C₆ alkylene, C₂-C₂₄-haloalkylene,and X is a hetero atom or group selected from the group consisting of 0,S and NH; and R⁵ represents a group of the general formula—R³—NH—C(═O)—X—R³-Q wherein R³ and X are as defined above andindependently selected, and Q represents an indicator and/or a referencedye derived from triangulenium compounds, acridinium compounds,ruthenium doped sol-gel particles, ruthenium-based compounds withα-diimine ligands, porphorin with Pt or Pd as the central metal atom,Ru(bpy)₂(dpp)Cl₂, Ru(bpy)₃Cl₂ a lanthanide containing complex, orpolymeric metal containing structure.
 2. The sol-gel matrix according toclaim 1, wherein the second polymer component is prepared frompolymerization of the second alkoxysilane and the additionalalkoxysilane.
 3. The sol-gel matrix according to claim 1, wherein Q isan indicator dye derived from 8-hydroxypyrene-1,3,6-trisulfonic acid(HPTS), fluorescein, or rhodamine B.
 4. The sol-gel matrix according toclaim 1, wherein the Lewis acid is a triagonal planar species.
 5. Thesol-gel matrix according to claim 4, wherein the Lewis acid is selectedfrom the group consisting of TiCl₃, AlCl₃, and BF₃, or solvates oretherates thereof.
 6. The sol-gel matrix according to claim 1, whereinthe first alkoxysilane is selected from the group consisting ofethyltriethoxysilane (ETEOS), methyltriethoxysilane (MTEOS),propyltriethoxysilane (PrTEOS), n-octyltriethoxysilane (n-octyl TEOS),methyltrimethoxysilane (MTMOS), aminopropyltrimethoxysilane (APTMOS),phenyltriethoxysilane (PhTEOS), and phenyl trimethoxysilane (PhTMOS). 7.The sol-gel matrix according to claim 1, wherein second alkoxysilane is3-glycidoxypropyltrimethoxysilane (GPTMS).
 8. A composite comprising alayer of sol-gel matrix according to claim 1 and a platform comprising amicrostructure area, wherein the sol-gel matrix is attached to themicrostructure area.
 9. The composite according to claim 8, wherein themicrostructure area comprises a plurality of pillars having a height inthe range of 0.1 μm to 500 μm and a distance between each pillar in therange of 0.1 μm to 500 μm.
 10. The composite according to claim 8,wherein the distance between each pillar is in the range of 5 to 40 μm,the height of the pillars is in the range of 11 to 40 μm and the widthof each pillar is in the range of 5 to 40 μm.
 11. The compositeaccording to claim 8, wherein the layer of the sol-gel matrix has athickness smaller than the height of the microstructure.
 12. Thecomposite according to claim 8, comprising an array of sol-gel matricesattached to different areas on the microstructure area.
 13. Thecomposite according to claim 8, wherein sol-gel matrix comprises anindicator or reference dye.
 14. The composite according to claim 13,wherein the sol-gel matrix includes at least two different indicator orreference dyes.
 15. The composite according to claim 8, wherein theplatform is an inner surface of a container or conduit for transportinga fluid.
 16. The composite according to claim 15, wherein the containercomprises an opening and cylindrical or tapered sides, and is closedopposite to the opening.
 17. The composite according to claim 8, whereinthe platform is an inner surface of a disposable container fortransporting a fluid.
 18. The composite according to claim 8, whereinthe microstructure area has been prepared by a process selected from thegroup consisting of injection molding, hot embossing, lasermicrostructuring, micromachining, chemical etching, and photoresistlayer structuring.
 19. A method of monitoring of a bioculture, themethod comprising the steps of: providing a composite according to claim13, applying the bioculture to the platform, exposing the sol-gel matrixto light, and detecting light emitted from the sol-gel matrix.